EP1076409B1 - Power control circuit of an electric consumer - Google Patents

Description

The invention relates to a circuit arrangement for power control of an electrical load, in particular an engine in a vacuum cleaner, through which the power of the consumer is controlled by a controllable semiconductor switching element and in which a current limiting circuit for load current limiting of the consumer is arranged.

Circuits for inrush current limiting are known in many forms, for example from the EP 0 678 271 A2 . DE 27 46 845 A1 . DE 25 39 543 A1 . DE 42 33 542 C1 . DE 29 35 807 A1 . EP 0 678 271 A2 . DE 34 44 745 A1 . DD 286 912 A5 . DE 197 55 368 A1 , Such inrush current limiting or soft-starting circuits are particularly useful for inductive loads with higher rated loads, since at their turn may result in very high inrush currents that carry a multiple of the rated current. By soft-start circuits ensures that mains fuses do not respond, because the respective consumer, in particular the engine of a handheld electrical device, in particular a vacuum cleaner or a power tool such as an angle grinder or a drill, an initially artificially limited inrush current is supplied, the after some time, if Electric motor has come to speed and no longer requires such a high current, takes higher values. The peak inrush currents are, for example, more than 50 A in the case of vacuum cleaners. The same problem arises with an abrupt or strong increase in the power of the consumer.

Otherwise, the motor is supplied with voltage by a control circuit. The control circuit has a semiconductor component for controlling the motor, for example a triac.

The disadvantage of a current limiting circuit is that it is lossy depending on the embodiment, which leads to an increased voltage drop in the entire circuit arrangement and thus causes a lower voltage to the motor, so that it has a lower power than at full utilization of the available Mains voltage would be possible.

Currently, these losses are reduced by expensive circuits, for example by microcontroller circuits or solutions with special flat gate circuits.

It is the object of the invention to improve a circuit arrangement of the type mentioned in such a way that the current limiting circuit consumes at least substantially no voltage after the end of the switch-on phase or a run-up phase.

This object is achieved with the circuit arrangement according to claim 1.

This eliminates the transition from the start-up phase to normal operation with a rated current that is far lower than the peak current during the start-up phase, so for example in a vacuum cleaner between 6 and 7 A, the electrical losses causing circuit elements of the current limiting circuit. The full mains voltage is thus available to supply the motor so that it operates at full power.

According to the invention, only a simple time-dependent actuator is used to turn off the current limiting circuit, so that in difference To use a microcontroller or a complex circuit a simple means is created to avoid power losses.

The invention can also be used in a circuit for power control as well as power control of the consumer. The switching means according to the invention is a time-dependent switch, which switches delayed, d. H. For example, closed or opened, depending on the circuit design and position of the actuator in the circuit or is a switching semiconductor element.

The time delay is inventively achieved either directly as a function of time after switching on the mains voltage or indirectly via the dependence of one or more operating states of consumption, such as a universal motor, or the environment of the consumer. By this is meant, for example, the heating of the environment, which is expressed for example by an increased resistance of a PTC resistor. Other thermal switches, such as bimetallic switches come into consideration.

The actuator is in any case mounted within the entire circuit arrangement, that when you turn on the device or when changing the operating conditions of the device, for example, by jumping to maximum power of the consumer, from a stand-by position out the entire process repeated.

In particular, the circuit arrangement can be used in a vacuum cleaner whose motor generates a negative pressure in the fan, so that after falling below a certain pressure value, a vacuum switch is actuated, which shuts off the loss-causing circuit elements of the current limiting circuit.

In addition, however, timers are also switches with an additional delayed switching contact, for example with a viscous-elastic system, electrical timer, for example consisting of an RC element, in particular in conjunction with a semiconductor device, such as a transistor, or thermoelectric bimetallic switch.

It is understood that the invention can be used in conjunction with any other current limiting circuits, in particular start-up current limiting circuits.

It is not absolutely necessary that no current at all flows through the current limiting circuit. Rather, it is also sufficient if, for example, by decreasing an electrical resistance by heating, a parallel to the current limiting circuit current path becomes electrically more conductive.

Further advantageous embodiments will become apparent from the dependent claims.

The invention will be described in embodiments with reference to FIGS FIGS. 1 to 8 explained in more detail. These show circuit arrangements of a phase control circuit and with a current limiting circuit.

An electrical load, in particular a motor 1, which serves, for example, as a fan motor in a vacuum cleaner, is controlled or regulated via a controllable semiconductor switching element 2 in its performance. The semiconductor switching element 2 is connected with its control terminal 3 to a power supply, which is formed by a phase control circuit. In this, a switch 4 is arranged, which is connected to a power terminal 5. After switching on the switch 4, the control terminal 3 of the semiconductor switching element 2 via a potentiometer 6 and about this in series resistors 7, 8 and 9 and a Diac 10th supplied as a driver with voltage so that it turns on in both half-waves of the feeding mains AC voltage to the motor 1.

Via a bridge circuit point 11, which is arranged between the resistors 8 and 9, a capacitor 12 is connected in parallel with the resistor 9, the diac 10 and the semiconductor switching element 2. The capacitor 12 is charged after switching on the voltage via the switch 4 via the potentiometer 6 and the resistors 7 and 8 depending on the position of the potentiometer 6 more or less quickly. If the voltage across the capacitor 12, regardless of its polarity, the breakdown voltage of Diacs 10, so this becomes conductive, so that the capacitor 12 discharges over a certain time through the resistor 9, through the control terminal 3 and a main terminal 13 of the semiconductor switching element 2, a load current flows to a terminal 14 of the motor 1.

The semiconductor switching element 2 is conductive as long as a certain current, the so-called holding current, flows through it. In this case, only one particular phase angle is utilized by the two half-waves of the alternating current signal in accordance with the position of the potentiometer 6 in order to drive the motor 1.

Between a bridge node 15, which is located between the resistors 7 and 8, and the terminal 14 of the motor 1, a current limiting circuit is arranged. This serves to limit the switching hysteresis, which occurs especially after switching on the switch 4, so when starting the engine 1. The current limiting circuit 16 therefore has a bridge rectifier circuit consisting of four diodes 17, 18, 19 and 20, the diodes 17 and 18 or 19 and 20 being respectively arranged so as to be permeable to the alternating half-waves of the alternating voltage. In two other bridge branches of the rectifier circuit are a Zener diode 21 and a Electrolytic capacitor 22 and a resistor 23 are arranged. Due to the arrangement of the diodes 17 to 20, the electrolytic capacitor 22 is supplied only with DC voltage, wherein the Zener diode 21 limits the voltage for charging the electrolytic capacitor 22. The mode of operation of the control limiting circuit 16 is thus that the electrolytic capacitor 22 is initially charged until reaching the maximum permitted voltage of the Zener diode 21 and the capacitor 12 is charged only after exceeding this voltage. The resistor 23 serves as a discharge resistor for the electrolytic capacitor 22.

However, since the current limiting circuit 16 itself consumes power, it is desirable only in the time after the power is turned on or after the power consumption of the load be increased to limit the hysteresis effect of the phase control circuit. After a certain period of time, which is different depending on the dimensioning of the resistors 7, 8 and 9 and the position of the potentiometer 6, the current limiting circuit 16 is switched off according to the invention, for which purpose a switch 24 arranged between the bridge circuit point 15 and the input of the current limiting circuit 16 is provided is.

Alternatively, instead of the switch 24 between the output of the current limiting circuit 16 and a bridge node 25, a switch 26 is provided ( Fig. 2 ).

In a further embodiment ( Fig. 3 ), a switch 27 is connected in parallel with the resistors 7 and 8 together with a resistor 28.

A switch 29 ( Fig. 4 ) switches the AC voltage either through the resistor 7 to the current limiting circuit 16, so for example after switching on the circuit or a strong power change, or the switch 29 switches the potentiometer 6 in series with the resistor 28, so that the current limiting circuit 16 is bypassed and the capacitor 12 is charged directly.

The in Fig. 3 illustrated switch 27 is in a preferred embodiment ( Fig. 5 ) executed as a vacuum switch 27a. When the motor 14 is configured as a blower motor, for example, in a vacuum cleaner, a negative pressure sensor communicating with the negative pressure switch 27a is disposed in the suction portion of the fan so that the negative pressure switch 27a closes when the pressure falls below a predetermined pressure, thereby bypassing the current limiting circuit 16.

Alternatively, the switch 27 is in a further embodiment ( Fig. 6 ) is formed as a temperature-dependent switch 27b. The switch 27b is, for example, a resistance decreasing with temperature, that is, preferably a PTC or an NTC resistor, which decreases as the temperature rises, so that the current path between the potentiometer 6 and the bridge node 11 becomes conductive.

In another embodiment ( Fig. 7 ) is provided that after switching on the switch 4, the current first flows through a parallel to the potentiometer 6 arranged resistor 30, wherein the path to the current limiting circuit 16 is free, it being ensured that the motor 1 during the switch-on regardless of the Position of the potentiometer 6 is supplied with a fixed predetermined voltage, which results in accordance with the dimensioning of the resistors 30, 9 and an additionally arranged in front of the bridge circuit point 11 resistor 31. Only after exceeding a certain temperature, for example, the temperature in the region of the Staorwicklung of the motor 1, a series-connected to the potentiometer 6, acted upon by this temperature resistor 32 is electrically conductive, so that the potentiometer 6 is effectively actuated by the operator. In this case, current flows through the current limiting circuit 16 only as long as a Parallel to the resistors 7 and 8 arranged vacuum switch 33 is not yet closed. When it closes after reaching a predetermined negative pressure, the current flows, bypassing the current limiting circuit 16 immediately either via the potentiometer 6 or the resistor 30 to the resistor 31 and charges the capacitor 12.

In another embodiment ( Fig. 8 ), a switch 33 with a time-delayed contact 34 is provided instead of the switch 4. The contact 34 switches after a certain, predetermined period of time, the current path 28 comprising the resistor to the control terminal 3, so that the current limiting circuit 16 is bypassed.

It is understood that the in Fig. 1 to 8 illustrated embodiments of the circuit for bypassing the current limiting circuit 16 are only exemplary. Generally, it is provided according to the invention, not only after completion of the switch-on, but also after the completion of a power increase phase of the consumer, in particular the motor 1, cancel the action of the current limiting circuit 16, including according to the invention either the current path through the current limiting circuit 16 interrupting switches 24, 26th , 27, 29 are provided with switch contacts or switch with a delayed switching contact, such as the switch 33, for example, based on a visco-elastic system, or electrical timers, such as RC elements, for example, in connection with a semiconductor device, for. As a transistor, a current through, or there are thermoelectric switches, for example in the form of NTC or PTC resistors or as a bimetallic switch provided. Likewise, it is also possible to provide other switching means which evaluate one or more operating variables of the electrical load after a successful run-up or after a power increase and accordingly clear current paths by which the current-limiting circuit 16 is bypassed. As to be detected Sizes are suitable in addition to the temperature, the pressure or the negative pressure, the voltage or the current within the circuit.

The invention can be used universally in all motor devices with a motor, such as a universal motor and one with current limiting, it being sufficient if the current limiting circuit consists of an RC element which is connected in parallel to the phase control circuit. By the use of the invention voltage losses are minimized by the current limiting circuit.

Claims (8)

1. Circuit arrangement for power control of an electrical consumer, particularly a motor (1) in a vacuum cleaner, by which the power of the consumer is controllable by a controllable semiconductor switching element (2) and in which a current limiting circuit (16) for load-current limitation of the consumer is arranged, characterised in that a switching means (24, 26, 27, 29; 27a, 27b; 33, 34), which is associated with the current limiting circuit and which after the conclusion of the start-up phase or of a run-up phase of the consumer is switchable in such a manner that the current limiting circuit (16) is at least substantially free of current, is provided, wherein the switching means (24, 26, 27, 29; 27a, 27b; 33, 34) is a switch (33, 34) switching with a time delay and wherein the time delay is attainable either directly in dependence on the time after the switching-on of the mains voltage or indirectly by way of the dependence of one or more operating states of the consumer or of the environment of the consumer.
2. Circuit arrangement according to claim 1, characterised in that the switching means is a switch (24, 26), which has switch contacts, at the input or output of the current limiting circuit (16).
3. Circuit arrangement according to claim 1, characterised in that the switching means is a switch (27) which is arranged in a current path parallel to an input resistance (7) of the current limiting circuit (16) and which is closable after the conclusion of the start-up or run-up phase of the consumer.
4. Circuit arrangement according to claim 1, characterised in that the switching means is a switch (29) between the input of the current limiting circuit (16) and a current path bypassing it, which switch can be switched over after the conclusion of the start-up or run-up phase of the consumer.
5. Circuit arrangement according to claim 3 or 4, characterised in that the switching means is a thermal switch.
6. Circuit arrangement according to claim 5, characterised in that the switch is a PTC or an NTC resistor (27b, 32).
7. Circuit arrangement according to any one of claims 1 to 4, characterised in that the switching means is a negative-pressure switch (27a).
8. Circuit arrangement according to claim 7, characterised in that the negative pressure switch (27a) is arranged in the air suction channel of a vacuum cleaner.

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